Genetic transformation of organisms with large genome fragments containing complete genes, with regulatory elements or clusters of genes, can contribute to the functional analysis of such genes. However, large inserts, such as those found on bacterial artificial chromosome (BAC) clones, are often not easy to transfer. We exploited an existing technique to convert BAC clones, containing genomic DNA fragments from the barley-covered smut fungus Ustilago hordei to binary BACs (BIBACs) to make them transferable by the Agrobacterium tumefaciens T-DNA transfer machinery. Genetic transformation of U. hordei with BAC clones using polyethylene glycol or electroporation is difficult. As a proof of concept, two BAC clones were successfully converted into BIBAC vectors and transferred by A. tumefaciens into U. hordei and U. maydis, the related corn smut fungi. Molecular analysis of the transformants showed that the T-DNA containing the BAC clones with their inserts was stably integrated into the U. hordei genome. A transformation frequency of approximately 10−4 was achieved both for U. hordei sporidia and protoplasts; the efficiencies were 25–30 times higher for U. maydis. The combination of in vivo recombineering technology for BAC clones and A. tumefaciens-mediated transformation of Ustilago species should pave the way for functional genomics studies.

Rhizoctonia solani, teleomorph Thanatephorus cucumeris, is a polyphagous necrotrophic plant pathogen of the Basidiomycete order that is split into 14 different anastomosis groups (AGs) based on hyphal interactions and host range. In this investigation, quantitative real-time PCR (qRT-PCR) techniques were used to determine potential pathogenicity factors of R. solani in the AG1-IA/rice and AG3/potato pathosystems. These factors were identified by mining for sequences of pathogen origin in a library of rice tissue infected with R. solani AG1-IA and comparing these sequences against the recently released R. solani AG3 genome. Ten genes common to both AGs and two specific to AG1-IA were selected for expression analysis by qRT-PCR. Results indicate that a number of genes are similarly expressed by AG1 and AG3 during the early stages of pathogenesis. Grouping of these pathogenicity factors based on relatedness of expression profiles suggests three key events are involved in R. solani pathogenesis: early host contact and infiltration, adjustment to the host environment, and pathogen proliferation through necrotic tissue. Further studies of the pathogenesis-associated genes identified in this project will enable more precise elucidation of the molecular mechanisms that allow for the widespread success of R. solani as a phytopathogen and allow for more targeted, effective methods of management.

Many fungal plant pathogens secrete an array of cell wall degrading enzymes mainly involved in the pathogenesis. In this work, a cDNA clone encoding an extracellular endo-1,4-β-glucanase (named PlEGL1) from the causal agent of the Corky Root Rot of tomato, Pyrenochaeta lycopersici, was isolated and characterized, in order to understand its putative role in the pathogenesis and its mechanism of action. Multiple alignment of the deduced amino acidic sequence shows a high homology with other endoglucanases from different phytopathogenic fungi and detects a well-defined conserved domain of the Glycosyl Hydrolase family 61 (GH61). In vitro, Plegl1 gene transcription is correlated to a cellulolytic activity of the fungus, regulated, in its turn, by the presence of sugar and/or cellulose in the culture medium. In the infected plants, expression level of Plegl1 is positively correlated to the development of the disease. PlEGL1 was heterologously expressed in Escherichia coli and the recombinant protein was purified and tested for its cellulolytic ability, showing a very weak activity, in agreement with all the endoglucanases belonging to GH61 family. The finding in this paper will provide the basis for further determination of biochemical properties of the PlEGL1 protein and its possible involvement in the host–pathogen interaction.

Since the secretory pathway is essential for Candida albicans to transition from a commensal organism to a pathogen, an understanding of how this pathway functions may be beneficial for identifying novel drug targets to prevent candidiasis. We have cloned the C. albicans KAR2 gene, which performs many roles during the translocation of proteins into the endoplasmic reticulum (ER) during the first committed step of the secretory pathway in many eukaryotes. Our results show that C. albicans KAR2 is essential, and that the encoded protein rescues a temperature-sensitive growth defect found in a Saccharomyces cerevisiae strain harboring a mutant form of the Kar2 protein. Additionally, S. cerevisiae containing CaKAR2 as the sole copy of this essential gene are viable, and ER microsomes prepared from this strain exhibit wild-type levels of post-translational translocation during in vitro translocation assays. Finally, ER microsomes isolated from a C. albicans strain expressing reduced amounts of KAR2 mRNA are defective for in vitro translocation of a secreted substrate protein, establishing a new method to study ER translocation in this organism. Together, these results suggest that C. albicans Kar2p functions during the translocation of proteins into the ER during the first step of the secretory pathway.

β-Glucan is an essential cell wall structural component in most fungi and its helical structure is important for maintenance of cell wall elasticity in fungi. The gene encoding β-1,3-glucan synthase in the entomopathogenic fungus Metarhizium acridum (MaFKS; HQ441252) was cloned. The function of MaFKS was analyzed by RNA interference (RNAi). FKS-RNAi transformants were more sensitive to agents that disturb the cell wall or cell membrane and to hyperosmotic stress than the wild type. In comparison with the wild type, aerial hyphae and conidial yield were obviously reduced in FKS-RNAi transformants on potato dextrose agar plates with Congo red, calcofluor white, sodium dodecyl sulfate, KCl, sorbitol or mannitol. The β-1,3-glucan content significantly decreased in FKS-RNAi transformants, indicating that MaFKS affects the synthesis of β-1,3-glucan in the fungal cell wall and confirming its role in the maintenance of cell wall integrity, hyperosmotic pressure tolerance and conidiation.

Members of the striatin family and their highly conserved interacting protein phocein/Mob3 are key components in the regulation of cell differentiation in multicellular eukaryotes. The striatin homologue PRO11 of the filamentous ascomycete Sordaria macrospora has a crucial role in fruiting body development. Here, we functionally characterized the phocein/Mob3 orthologue SmMOB3 of S. macrospora. We isolated the gene and showed that both, pro11 and Smmob3 are expressed during early and late developmental stages. Deletion of Smmob3 resulted in a sexually sterile strain, similar to the previously characterized pro11 mutant. Fusion assays revealed that ∆Smmob3 was unable to undergo self-fusion and fusion with the pro11 strain. The essential function of the SmMOB3 N-terminus containing the conserved mob domain was demonstrated by complementation analysis of the sterile S. macrospora ∆Smmob3 strain. Downregulation of either pro11 in ∆Smmob3, or Smmob3 in pro11 mutants by means of RNA interference (RNAi) resulted in synthetic sexual defects, demonstrating for the first time the importance of a putative PRO11/SmMOB3 complex in fruiting body development.

Coniochaeta ligniaria NRRL30616 is an ascomycete that grows with yeast-like appearance in liquid culture. The strain has potential utility for conversion of fibrous biomass to fuels or chemicals. Furans and other inhibitory compounds in lignocellulosic biomass are metabolized by NRRL30616, facilitating subsequent microbial fermentation of biomass sugars. This study undertook initial characterization of the genetic system of C.ligniaria NRRL30616. Transformation using hygromycin as a dominant selectable marker was achieved using protoplasts generated by incubating cells in 1% (v/v) β-mercaptoethanol, followed by cell wall-digesting enzymes. Thirteen chromosomes with an estimated total size of 30.1 Mb were detected in C. ligniaria. The GC content of chromosomal DNA and of coding regions from cDNA sequences were 49.2 and 51.9%, respectively. This study is the first report of genome size, electrophoretic karyotype, and transformation system for a member of the Coniochaetales.

The cAMP–PKA is the major glucose-sensing pathway that controls sexual differentiation in Schizosaccharomyces pombe. Sequencing from the pka1 locus of recessive sam mutants, in which cells are highly inclined to sexual differentiation, led to the identification of mutations in the pka1 locus in sam5 (pka1-G441E) and sam7 (pka1-G441R). Rst2 and Ste11 proteins were induced and localized to the nucleus of sam5 and sam7 mutants even under rich glucose conditions, indicating that the function of Pka1 was completely abolished by mutations. Pka1-G441E and Pka1-G441R mutant proteins reside in the cytoplasm, even under glucose-rich conditions, while wild-type Pka1 resides in the nucleus, indicating that the functionality of Pka1 is important for its nuclear localization. This is supported by the observation that the Pka1-T356A mutant, which partially lacks Pka1 function, was localized to both the cytoplasm and the nucleus, but an active phosphomimetic Pka1-T356D mutant prtotein was localized to the nucleus under glucose-rich conditions. In addition to the basal phosphorylation of Pka1 at T356, hyperphosphorylation of Pka1 was observed under glucose-starved conditions, and such hyperphosphorylation was not observed in pka1-G441E, pka1-G441R, pka1-T356A or pka1-T356D mutants. As these mutant proteins failed to interact with a regulatory subunit Cgs1, hyperphosphorylation of Pka1 mutant proteins was considered to be dependent on Cgs1 interaction. Consistent with a role for Cgs1 in Pka1 phosphorylation, we detected the formation of a Cgs1–Pka1 complex prior to Pka1 hyperphosphorylation. Together, these results indicate that nuclear localization of Pka1 depends on its activity and hyperphosphorylation of Pka1 depends on Cgs1 interaction.

The msa2/nrd1 gene encodes an RNA-binding protein that negatively regulates sexual differentiation of fission yeast Schizosaccharomyces pombe by repressing the Ste11-regulated genes. However, it is not known how Msa2 regulates sexual differentiation, and to characterize its role, we altered the msa2 gene by inducing point mutations and tested the resulting mutants for their ability to inhibit sexual differentiation and their suppressive effect on a temperature sensitive pat1 mutant. Several amino acids were found to be important, including three phenylalanine residues (F153, F245 and F453) in the three consensus RNA recognition motifs (RRMs) and a threonine residue (T126) that normally functions as a phosphorylation site. Results indicated that Msa2 was negatively regulated by phosphorylation that arose from Spk1-mediated pheromone signaling. Msa2 also regulated the Ste11 protein level coordinating with Cpc2, a ribosomal-associated protein. In addition, Msa2 was detected in stress granules that co-localized with Pabp in the cytosol under conditions of glucose starvation. Msa2 may regulate the translation of Ste11, be a component of stress granules that form in response to glucose starvation, and regulate the sexual differentiation of S. pombe.

The aim of this study was to apply a generated Δtku70 strain with increased homologous recombination efficiency from the mycoparasitic fungus Trichoderma virens for studying the involvement of laccases in the degradation of sclerotia of plant pathogenic fungi. Inactivation of the non-homologous end-joining pathway has become a successful tool in filamentous fungi to overcome poor targeting efficiencies for genetic engineering. Here, we applied this principle to the biocontrol fungus T. virens, strain I10, by deleting its tku70 gene. This strain was subsequently used to delete the laccase gene lcc1, which we found to be expressed after interaction of T. virens with sclerotia of the plant pathogenic fungi Botrytis cinerea and Sclerotinia sclerotiorum. Lcc1 was strongly upregulated at early colonization of B. cinerea sclerotia and steadily induced during colonization of S. sclerotiorum sclerotia. The Δtku70Δlcc1 mutant was altered in its ability to degrade the sclerotia of B. cinerea and S. sclerotiorum. Interestingly, while the decaying ability for B. cinerea sclerotia was significantly decreased, that to degrade S. sclerotiorum sclerotia was even enhanced, suggesting the operation of different mechanisms in the mycoparasitism of these two types of sclerotia by the laccase LCC1.